RU231122U1 - DEVICE FOR DETERMINING THE POSITION OF BLOOD VESSELS IN THE NECK AREA IN SAGITTAL, FRONTAL AND HORIZONTAL ANATOMICAL PLANES DURING ULTRASONIC EXAMINATION - Google Patents

Abstract

The utility model is intended for diagnostics of diseases, study of intravital anatomy and topography of blood vessels in the neck area, assessment of some criteria of surgical approaches and creation of computer models. Visualization of objects is carried out during ultrasound examination. The technical result is the location of the linear sensor strictly in a certain anatomical plane (sagittal, frontal and horizontal) in accordance with the readings of one three-plane level installed on the sensor, which allows intravital and simultaneously during ultrasound examination to determine the position of blood vessels in the neck area with higher accuracy.

Description

Field of technology

The utility model relates to medicine and is intended for diagnosing diseases and studying the intravital anatomy and topography of blood vessels in the neck area during ultrasound examination.

The ultrasound diagnostic method is an accessible lifetime diagnostic method that allows for precise determination of the shape and size of blood vessels in the neck area. At the same time, the ultrasound scanner allows for obtaining an image of anatomical objects only in one plane of the body section, corresponding to the course of the ultrasound wave. The direction of the wave depends on the position of the sensor in the doctor's hand and does not necessarily correspond exactly to the anatomical planes (sagittal, frontal and horizontal). As a result, determining the exact anatomical position of blood vessels in the neck area is difficult.

Determining the exact anatomical position of blood vessels is essential in ultrasound examination, but is not always technically possible (Velkoborski H.-J. Ultrasound Diagnostics of Head and Neck Diseases / Hans-Jürgen Velkoborski, Peter Jecker, Jan Maurer, Wolf Jürgen Mann; translated from German. - Moscow: MEDpress-inform, 2016. - 176 p: ill. ISBN 978-5-00030-282-8). At the same time, ultrasound examination can be used both for diagnosing diseases and for studying the intravital anatomy and topography of blood vessels in the neck. For intravital anatomical examination using the ultrasound method, it is necessary to determine the position of the blood vessels in the neck in a certain anatomical plane (sagittal, frontal and horizontal). For this, the ultrasound scanner sensor must be installed strictly in a certain anatomical plane, which is very difficult to do using traditional ultrasound techniques.

State of the art

Known is the "Method for Finding an Anatomical Plane Parallel to the Occlusion Plane" (patent for invention of the Russian Federation. Authors: Roshchin E.M., Panteleev V.D., Roshchina A.V. RU2471452 C1, 11.04.2013). The invention relates to the field of medicine, namely to orthopedic dentistry, and is intended to find an anatomical plane that is parallel to the occlusion plane. It is proposed to determine the anatomical planes corresponding to the interincisor papilla of the upper jaw and the apex of the styloid process, the location of which is proposed to be determined by palpation, using bone and muscle landmarks.

The disadvantage of this method is that it does not use ultrasound examination, which allows visualization of the deeper tissues of the human body, and that one, rather than three main mutually perpendicular anatomical planes are used, which specify the definition of the spatial arrangement of blood vessels in space. There are three such planes: sagittal, frontal, horizontal. These planes can be drawn through any point of the human body. The relationship of blood vessels to the main anatomical projection planes is important in systems of intravital medical imaging. This assessment is necessary both for the diagnosis of pathological conditions and for anatomical studies.

The essence of the utility model

To position an object in a strictly defined plane, bubble levels are widely used. Accordingly, for three anatomical planes (sagittal, frontal and horizontal), three bubble levels are required, which must be installed on the ultrasound scanner sensor. Each of the three bubble levels is installed and adjusted separately, in accordance with mutually perpendicular anatomical planes to determine the exact spatial location of blood vessels in the neck area for the purpose of diagnosing pathological conditions and for anatomical studies.

The main task that the device is aimed at solving is the ability to describe the anatomical position of an anatomical object in the neck area in a certain anatomical plane (sagittal, frontal and horizontal) for diagnosing vascular diseases, describing the intravital anatomy and topography of the neck area, assessing some criteria for surgical approaches and creating computer models with greater accuracy, since one three-plane bubble level attached to the ultrasound scanner sensor is used for this.

The technical result of implementing the claimed utility model is the ability to determine the position of blood vessels during an ultrasound examination of the neck area in a certain anatomical plane (sagittal, frontal and horizontal) during a lifetime and simultaneously by fixing one three-plane bubble level to the surface of the ultrasound scanner sensor and can be used to describe the lifetime anatomy and topography, diagnose pathological processes in the neck area, evaluate certain criteria for surgical approaches, and create computer models.

The technical result is achieved by the fact that in order to increase the accuracy of the anatomical measurements performed during the scientific study, a more rigorous control of the ultrasound sensor position is carried out during the measurements and each ultrasound section is carried out in accordance with the anatomical planes. For this purpose, not three different bubble levels are used, fixed on one sensor, which makes this process more complicated and the result less predictable, since it is much more difficult to carry out precise adjustment of three bubble levels at once, but one compact three-plane bubble level. In addition, the attachment of three different bubble levels to a much greater extent increases the total volume of the ultrasound scanner sensor, changes its shape, which creates inconvenience for the doctor when performing an ultrasound examination.

The essence of the utility model is explained in Fig. 1, where it is proposed to use a three-plane bubble level, which is a measuring instrument in the form of a cube, made of plastic, wood or metal. Bubble levels are attached to the three surfaces of the cube, which are transparent flasks filled with a transparent liquid.

The device itself is a cubic base (2), on which three flat bubble levels (1) are rigidly fixed in three different mutually perpendicular planes. A clamp for fixation (3) is provided on the base of the base. The device is fixed on the sensor of the ultrasound scanner in any possible way that does not destroy the integrity of the sensor handle structure. The following options for fastening are possible: glue, strap-tie, clamp-collar, etc.

If it is necessary to conduct a study in the horizontal plane, the assessment is carried out using one bubble level, in the frontal plane - using another, and in the vertical plane - using a third.

When the device is attached to the ultrasound scanner sensor, it allows tracking the spatial position of the sensor depending on the plane of examination without additional adjustment.

Implementation of a utility model

The device works as follows. Ultrasound scanning of the neck is performed using the standard method with the person lying on his back, the head is positioned straight. A linear sensor with a frequency of 5-7 MHz is used. After applying the gel, the sensor is positioned in accordance with the anatomical plane (sagittal, frontal and horizontal).

To obtain an image in the sagittal plane, a linear sensor with a bubble level installed on it is positioned in the sagittal plane in the neck area in accordance with the level readings (Fig. 2). As a result, a scanogram of the neck area in the sagittal plane is obtained (Fig. 3).

To obtain an image in the horizontal plane, the position of the linear sensor with the bubble level installed on it is changed and placed in the horizontal plane (Fig. 4). As a result, a scanogram of the neck area in the horizontal plane is obtained (Fig. 5).

To obtain an image in the frontal plane of the neck area, a linear sensor with a bubble level installed on it is positioned in accordance with the level readings in the frontal plane (Fig. 6). As a result, a scanogram of the neck area in the frontal plane is obtained (Fig. 7).

Thus, the proposed utility model allows for intravital and simultaneous determination of the localization of the pathological process with greater accuracy during ultrasound examination, since the ultrasound scanner sensor is located strictly in the frontal anatomical plane due to fixation to the surface of the bubble level sensor.

Example of use

An example of a specific use of the utility model is shown in Fig. 8. The image was obtained during an ultrasound examination of a human neck in the frontal plane (male, 65 years old). A linear sensor with a frequency of 5-7 MHz is used. The developed method was used in the analysis of the results of an ultrasound examination for the purpose of an intravital study of the anatomical structures of the neck organs, as well as pathological processes. An atherosclerotic plaque is observed on the intima of the left common carotid artery (indicated by the arrow).

Claims (1)

A device for determining the position of blood vessels in the neck region in the sagittal, frontal and horizontal anatomical planes during ultrasound examination, comprising a cubic base with a bracket for fastening to the handle of an ultrasound scanner sensor, wherein three bubble levels are fixed on the surface of the cubic base in three different mutually perpendicular planes for obtaining images in the sagittal, frontal and horizontal anatomical planes.